DE3417770C2 - - Google Patents

Description

The invention relates to a check valve in the preamble of Main claim specified Art.

A known such check valve (DE-OS 28 52 816) has legs flow element adjoin the outlet channel of the valve housing the cylinder with damping pistons. The damping of the closing movement the closure part is created by vacuum formation in the cylinder. Ent there is only one relative per unit area of the damping piston low damping force. Requires a large damping force therefore a large piston diameter, which is a correspondingly large construction length of the check valve. By the transverse arrangement of the Influencing member and the lifting rod has the advantage that their length and stroke have no influence on the check valve length are. However, this advantage is due to the large piston diameter destroyed. Swing check valves with a short overall length can be therefore do not realize. The connecting rod also proves to be unfavorable like movement of the lifting rod, the damping piston a tilting movement imposes. This results in the sealing ring for the damping piston the risk of premature destruction by gap extrusion.

Otherwise, this known solution is not for check valves with Several closure parts are suitable if their pivot axes on mutually facing closure part edges are provided. The influencing element would then lie in each case in the opening area of the adjacent closure part.

In a known check valve of another type (DE-OS 29 33 265) the damping cylinder and piston are arranged in the inlet duct. These Solution would be transferred to non-return valves with several closure parts bar without their opening movements being hindered. However, be demand the damping cylinder with piston and the lifting rod relatively  much overall length in the valve housing. For swing check valves with a short construction length is therefore unsuitable.

The invention has for its object a check valve to create the type mentioned, in which the influencing element and the lifting rod takes up very little valve body length. Here is the solution equally for swing check valves with only one and those with several closure parts may be suitable.

This is due to the features of the invention specified in the main claim Task solved.

The coupling means between the lifting rod and the closure part leave one exact linear guidance and movement of lifting rod and influencing element to. This allows the lifting rod side before the z. B. Pistons of interference solution member a pressure chamber can be arranged so that the interference not due to - physically - limited vacuum education behind, but by almost any increase in pressure the piston arises. Even with an influencing element of a small size A large influencing force can be generated in diameter. Leg Flow element and lifting rod therefore require very little valve Housing length, so that check valves with a very short length can be realized. As a result of the linear movement, column extrusion and the resulting premature destruction of any existing ones Sealing rings are eliminated. Because influencer as well Lifting rod on the entry side and thus outside the closure part movement supply space, the solution according to the invention is also for back flaps with several locking parts suitable.

The subclaims have advantageous developments of the invention for Object.

In an embodiment according to claims 2 and 3, the form generates an actuating force in the valve opening direction on the stepped piston. Here through - if z. B. the stepped piston as a damping device serves - the coupling means when opening the closure part in their  Active starting position are brought without a return spring is necessary. The restoring force therefore changes analogously to the form. A disadvantageously high restoring force at low pressure can thereby ver be avoided. With a return spring, however, would be the return force always the same and therefore possibly with less prevailing Closing force too large.

A particularly advantageous solution for check valves with two Ver closing parts, so-called double flaps, claim 4 has the opposite was standing. Each of the two independently moving ver a separate influencing element is assigned to the closing parts. Without Synchronization mechanisms for the closure part movement can therefore the most favorable influence for each of the closure parts, e.g. B. damping the closing movement can be achieved.

In the drawing, an embodiment of the Invention is in section check valve with two acting as a damping device Influencing elements shown in partial open.

The check valve has a short valve housing 1 , the z. B. can be trapped between flanges, not shown, of a fluid line. The valve housing 1 has an inlet channel 2 with a crosspiece 3 , an outlet channel 4 and a valve seat 5 . With the latter two act together in the outlet duct 4 arranged semicircular shutter members 6, the downstream at their adjacent edges on two of the cross bar 3 pivot axes are mounted pivotably. 7

The valve housing 1 also has two diametrically opposed pressure chambers 9 which extend substantially transversely to the longitudinal axis 8 of the valve housing 1 . In each of them is the part 10 of a stepped piston which is larger in diameter, while its part 11 , which is smaller in diameter, extends through the housing wall 12 into the inlet channel 2 . A lifting rod 13 is connected to the stepped piston part 11 . The two lifting rods 13 also extend transversely to the longitudinal axis 8 of the valve housing and parallel to the valve seat 5 from the housing wall 12 to the transverse web 3 . They are guided with their end remote from the piston. In front of the crosspiece 3 , each lifting rod 13 carries a lifting driver 14 designed as a stop collar. Both closure parts 6 have noses 15 on the inlet side with flanks 16 which engage on the end faces of the drivers 14 facing the stepped piston part 11 .

With normal media flow in the direction of the arrow (forward flow), the two closure parts 6 are in the open position. The admission pressure acting on the two stepped piston parts 11 holds the stepped pistons 10, 11 in their shown active position defined by stop rings 17 .

When the forward flow ends, the two closure parts 6 move in the closing direction. As soon as they reach the open position shown in the drawing, the lugs 15 of the closure parts 6 come to rest with their flanks 16 on the lifting drivers 14 . For further closing of the closing energy acting on the closing parts 6, the resistance to be overcome is opposed to the step piston parts 10 by a damping medium located in the pressure chambers 9 . The remaining closing movement is therefore damped.

As soon as the non-return valve opens again as a result of a further forward flow, the step pistons 10, 11 together with the two lifting rods 13 and lifting drivers 14 are brought into the illustrated starting and starting position by the admission pressure.

Since each closure part is assigned its own damping device 9, 10, 11, 13-17 , the damping takes place individually for each of the closure parts 6 that move independently of one another, so that optimal damping results can be achieved on the non-return valve. The structure of the two damping devices 9, 10, 11, 13-17 is the same and, moreover, simple and inexpensive to manufacture.

The influencing element could be used instead of a piston Membrane or be provided with a bellows, or it could e.g. B. find a friction member use.

Claims (5)

1. Check valve with

• a valve housing which has an inlet and an outlet channel,
• at least one closure part pivotably mounted about an axis in the outlet channel,
• - At least one lifting influencing element and
• at least one lifting rod projecting into the valve housing substantially transversely to the longitudinal axis of the valve housing, with which the influencing member is connected on the one hand and with which the closure part interacts,

characterized in that

• - The lifting rod ( 13 ) runs in the inlet channel ( 2 ) of the valve housing ( 1 ) and carries a lifting driver ( 14 ) and
• - On the closure part ( 6 ) on the entry side, a nose ( 15 ) is provided, which has a flank ( 16 ) engaging on at least part of the closure part pivot path on the lifting driver ( 14 ).

2. Non-return valve according to claim 1, characterized in that

• the lifting rod ( 13 ) passes through the inlet channel ( 2 ) from an area ( 12 ) remote from the closure part pivot axis ( 7 ) to an area ( 3 ) close to the closure part pivot axis ( 7 ),
• - The influencing element ( 9-11, 17 ) is located at the end of the lifting rod ( 13 ) remote from the swivel axis,
• - The lifting driver ( 14 ) is arranged in the region of the lifting rod ( 13 ) near the pivot axis and
• - The nose ( 15 ) engages on the influencing member ( 10, 11 ) facing the end face of the lifting driver ( 14 ).

3. Non-return valve according to one or more of the preceding claims, characterized in that the influencing member has a pressure chamber ( 9 ) and a step piston, the part ( 10 ) of larger diameter within the pressure chamber ( 9 ) is arranged while the piston part ( 11 ) smaller diameter extends to the inlet channel ( 2 ). 4. Non-return valve according to one or more of the preceding claims, characterized in that two closure parts ( 6 ) which are pivotably mounted on their adjacent edges, each of which has a nose ( 15 ) with a flank ( 16 ) on the inlet side, and two diametrically opposed influencing members ( 10, 11 ) together with lifting rods ( 13 ) and lifting drivers ( 14 ) are provided.